import torch
import einops
import hashlib
import numpy as np
import torch.nn as nn

import modules.processing

from enum import Enum
from scripts.logging import logger
from modules import devices, lowvram, shared, scripts

cond_cast_unet = getattr(devices, 'cond_cast_unet', lambda x: x)

from ldm.modules.diffusionmodules.util import timestep_embedding
from ldm.modules.diffusionmodules.openaimodel import UNetModel
from ldm.modules.attention import BasicTransformerBlock
from ldm.models.diffusion.ddpm import extract_into_tensor

from modules.prompt_parser import MulticondLearnedConditioning, ComposableScheduledPromptConditioning, ScheduledPromptConditioning


POSITIVE_MARK_TOKEN = 1024
NEGATIVE_MARK_TOKEN = - POSITIVE_MARK_TOKEN
MARK_EPS = 1e-3


def prompt_context_is_marked(x):
    t = x[..., 0, :]
    m = torch.abs(t) - POSITIVE_MARK_TOKEN
    m = torch.mean(torch.abs(m)).detach().cpu().float().numpy()
    return float(m) < MARK_EPS


def mark_prompt_context(x, positive):
    if isinstance(x, list):
        for i in range(len(x)):
            x[i] = mark_prompt_context(x[i], positive)
        return x
    if isinstance(x, MulticondLearnedConditioning):
        x.batch = mark_prompt_context(x.batch, positive)
        return x
    if isinstance(x, ComposableScheduledPromptConditioning):
        x.schedules = mark_prompt_context(x.schedules, positive)
        return x
    if isinstance(x, ScheduledPromptConditioning):
        cond = x.cond
        if prompt_context_is_marked(cond):
            return x
        mark = POSITIVE_MARK_TOKEN if positive else NEGATIVE_MARK_TOKEN
        cond = torch.cat([torch.zeros_like(cond)[:1] + mark, cond], dim=0)
        return ScheduledPromptConditioning(end_at_step=x.end_at_step, cond=cond)
    return x


disable_controlnet_prompt_warning = True
# You can disable this warning using disable_controlnet_prompt_warning.


def unmark_prompt_context(x):
    if not prompt_context_is_marked(x):
        # ControlNet must know whether a prompt is conditional prompt (positive prompt) or unconditional conditioning prompt (negative prompt).
        # You can use the hook.py's `mark_prompt_context` to mark the prompts that will be seen by ControlNet.
        # Let us say XXX is a MulticondLearnedConditioning or a ComposableScheduledPromptConditioning or a ScheduledPromptConditioning or a list of these components,
        # if XXX is a positive prompt, you should call mark_prompt_context(XXX, positive=True)
        # if XXX is a negative prompt, you should call mark_prompt_context(XXX, positive=False)
        # After you mark the prompts, the ControlNet will know which prompt is cond/uncond and works as expected.
        # After you mark the prompts, the mismatch errors will disappear.
        if not disable_controlnet_prompt_warning:
            logger.warning('ControlNet Error: Failed to detect whether an instance is cond or uncond!')
            logger.warning('ControlNet Error: This is mainly because other extension(s) blocked A1111\'s \"process.sample()\" and deleted ControlNet\'s sample function.')
            logger.warning('ControlNet Error: ControlNet will shift to a backup backend but the results will be worse than expectation.')
            logger.warning('Solution (For extension developers): Take a look at ControlNet\' hook.py '
                  'UnetHook.hook.process_sample and manually call mark_prompt_context to mark cond/uncond prompts.')
        mark_batch = torch.ones(size=(x.shape[0], 1, 1, 1), dtype=x.dtype, device=x.device)
        uc_indices = []
        context = x
        return mark_batch, uc_indices, context
    mark = x[:, 0, :]
    context = x[:, 1:, :]
    mark = torch.mean(torch.abs(mark - NEGATIVE_MARK_TOKEN), dim=1)
    mark = (mark > MARK_EPS).float()
    mark_batch = mark[:, None, None, None].to(x.dtype).to(x.device)
    uc_indices = mark.detach().cpu().numpy().tolist()
    uc_indices = [i for i, item in enumerate(uc_indices) if item < 0.5]
    return mark_batch, uc_indices, context


def create_random_tensors_hacked(*args, **kwargs):
    result = modules.processing.create_random_tensors_original(*args, **kwargs)
    p = kwargs.get('p', None)
    if p is None:
        return result
    controlnet_initial_noise_modifier = getattr(p, 'controlnet_initial_noise_modifier', None)
    if controlnet_initial_noise_modifier is not None:
        x0 = controlnet_initial_noise_modifier
        if result.shape[2] != x0.shape[2] or result.shape[3] != x0.shape[3]:
            return result
        x0 = x0.to(result.dtype).to(result.device)
        ts = torch.tensor([p.sd_model.num_timesteps - 1] * result.shape[0]).long().to(result.device)
        result = p.sd_model.q_sample(x0, ts, result)
        logger.info(f'[ControlNet] Initial noise hack applied to {result.shape}.')
    return result


if getattr(modules.processing, 'create_random_tensors_original', None) is None:
    modules.processing.create_random_tensors_original = modules.processing.create_random_tensors

modules.processing.create_random_tensors = create_random_tensors_hacked


class ControlModelType(Enum):
    """
    The type of Control Models (supported or not).
    """

    ControlNet = "ControlNet, Lvmin Zhang"
    T2I_Adapter = "T2I_Adapter, Chong Mou"
    T2I_StyleAdapter = "T2I_StyleAdapter, Chong Mou"
    T2I_CoAdapter = "T2I_CoAdapter, Chong Mou"
    MasaCtrl = "MasaCtrl, Mingdeng Cao"
    GLIGEN = "GLIGEN, Yuheng Li"
    AttentionInjection = "AttentionInjection, Lvmin Zhang"  # A simple attention injection written by Lvmin
    StableSR = "StableSR, Jianyi Wang"
    PromptDiffusion = "PromptDiffusion, Zhendong Wang"
    ControlLoRA = "ControlLoRA, Wu Hecong"


# Written by Lvmin
class AutoMachine(Enum):
    """
    Lvmin's algorithm for Attention/AdaIn AutoMachine States.
    """

    Read = "Read"
    Write = "Write"


class TorchHijackForUnet:
    """
    This is torch, but with cat that resizes tensors to appropriate dimensions if they do not match;
    this makes it possible to create pictures with dimensions that are multiples of 8 rather than 64
    """

    def __getattr__(self, item):
        if item == 'cat':
            return self.cat

        if hasattr(torch, item):
            return getattr(torch, item)

        raise AttributeError("'{}' object has no attribute '{}'".format(type(self).__name__, item))

    def cat(self, tensors, *args, **kwargs):
        if len(tensors) == 2:
            a, b = tensors
            if a.shape[-2:] != b.shape[-2:]:
                a = torch.nn.functional.interpolate(a, b.shape[-2:], mode="nearest")

            tensors = (a, b)

        return torch.cat(tensors, *args, **kwargs)


th = TorchHijackForUnet()


class ControlParams:
    def __init__(
            self,
            control_model,
            preprocessor,
            hint_cond,
            weight,
            guidance_stopped,
            start_guidance_percent,
            stop_guidance_percent,
            advanced_weighting,
            control_model_type,
            hr_hint_cond,
            global_average_pooling,
            soft_injection,
            cfg_injection,
            **kwargs  # To avoid errors
    ):
        self.control_model = control_model
        self.preprocessor = preprocessor
        self._hint_cond = hint_cond
        self.weight = weight
        self.guidance_stopped = guidance_stopped
        self.start_guidance_percent = start_guidance_percent
        self.stop_guidance_percent = stop_guidance_percent
        self.advanced_weighting = advanced_weighting
        self.control_model_type = control_model_type
        self.global_average_pooling = global_average_pooling
        self.hr_hint_cond = hr_hint_cond
        self.used_hint_cond = None
        self.used_hint_cond_latent = None
        self.used_hint_inpaint_hijack = None
        self.soft_injection = soft_injection
        self.cfg_injection = cfg_injection

    @property
    def hint_cond(self):
        return self._hint_cond

    # fix for all the extensions that modify hint_cond,
    # by forcing used_hint_cond to update on the next timestep
    # hr_hint_cond can stay the same, since most extensions dont modify the hires pass
    # but if they do, it will cause problems
    @hint_cond.setter
    def hint_cond(self, new_hint_cond):
        self._hint_cond = new_hint_cond
        self.used_hint_cond = None
        self.used_hint_cond_latent = None
        self.used_hint_inpaint_hijack = None


def aligned_adding(base, x, require_channel_alignment):
    if isinstance(x, float):
        if x == 0.0:
            return base
        return base + x

    if require_channel_alignment:
        zeros = torch.zeros_like(base)
        zeros[:, :x.shape[1], ...] = x
        x = zeros

    # resize to sample resolution
    base_h, base_w = base.shape[-2:]
    xh, xw = x.shape[-2:]

    if xh > 1 or xw > 1:
        if base_h != xh or base_w != xw:
            # logger.info('[Warning] ControlNet finds unexpected mis-alignment in tensor shape.')
            x = th.nn.functional.interpolate(x, size=(base_h, base_w), mode="nearest")

    return base + x


# DFS Search for Torch.nn.Module, Written by Lvmin
def torch_dfs(model: torch.nn.Module):
    result = [model]
    for child in model.children():
        result += torch_dfs(child)
    return result


def predict_start_from_noise(ldm, x_t, t, noise):
    return extract_into_tensor(ldm.sqrt_recip_alphas_cumprod, t, x_t.shape) * x_t - extract_into_tensor(ldm.sqrt_recipm1_alphas_cumprod, t, x_t.shape) * noise


def predict_noise_from_start(ldm, x_t, t, x0):
    return (extract_into_tensor(ldm.sqrt_recip_alphas_cumprod, t, x_t.shape) * x_t - x0) / extract_into_tensor(ldm.sqrt_recipm1_alphas_cumprod, t, x_t.shape)


def blur(x, k):
    y = torch.nn.functional.pad(x, (k, k, k, k), mode='replicate')
    y = torch.nn.functional.avg_pool2d(y, (k*2+1, k*2+1), stride=(1, 1))
    return y


class TorchCache:
    def __init__(self):
        self.cache = {}

    def hash(self, key):
        v = key.detach().cpu().numpy().astype(np.float32)
        v = (v * 1000.0).astype(np.int32)
        v = np.ascontiguousarray(v.copy())
        sha = hashlib.sha1(v).hexdigest()
        return sha

    def get(self, key):
        key = self.hash(key)
        return self.cache.get(key, None)

    def set(self, key, value):
        self.cache[self.hash(key)] = value


class UnetHook(nn.Module):
    def __init__(self, lowvram=False) -> None:
        super().__init__()
        self.lowvram = lowvram
        self.model = None
        self.sd_ldm = None
        self.control_params = None
        self.attention_auto_machine = AutoMachine.Read
        self.attention_auto_machine_weight = 1.0
        self.gn_auto_machine = AutoMachine.Read
        self.gn_auto_machine_weight = 1.0
        self.current_style_fidelity = 0.0
        self.current_uc_indices = None

    @staticmethod
    def call_vae_using_process(p, x, batch_size=None, mask=None):
        vae_cache = getattr(p, 'controlnet_vae_cache', None)
        if vae_cache is None:
            vae_cache = TorchCache()
            setattr(p, 'controlnet_vae_cache', vae_cache)
        try:
            if x.shape[1] > 3:
                x = x[:, 0:3, :, :]
            x = x * 2.0 - 1.0
            if mask is not None:
                x = x * (1.0 - mask)
            x = x.type(devices.dtype_vae)
            vae_output = vae_cache.get(x)
            if vae_output is None:
                with devices.autocast():
                    vae_output = p.sd_model.encode_first_stage(x)
                    vae_output = p.sd_model.get_first_stage_encoding(vae_output)
                vae_cache.set(x, vae_output)
                logger.info(f'ControlNet used {str(devices.dtype_vae)} VAE to encode {vae_output.shape}.')
            latent = vae_output
            if batch_size is not None and latent.shape[0] != batch_size:
                latent = torch.cat([latent.clone() for _ in range(batch_size)], dim=0)
            latent = latent.type(devices.dtype_unet)
            return latent
        except Exception as e:
            logger.error(e)
            raise ValueError('ControlNet failed to use VAE. Please try to add `--no-half-vae`, `--no-half` and remove `--precision full` in launch cmd.')

    def guidance_schedule_handler(self, x):
        for param in self.control_params:
            current_sampling_percent = (x.sampling_step / x.total_sampling_steps)
            param.guidance_stopped = current_sampling_percent < param.start_guidance_percent or current_sampling_percent > param.stop_guidance_percent

    def hook(self, model, sd_ldm, control_params, process):
        self.model = model
        self.sd_ldm = sd_ldm
        self.control_params = control_params

        outer = self

        def process_sample(*args, **kwargs):
            # ControlNet must know whether a prompt is conditional prompt (positive prompt) or unconditional conditioning prompt (negative prompt).
            # You can use the hook.py's `mark_prompt_context` to mark the prompts that will be seen by ControlNet.
            # Let us say XXX is a MulticondLearnedConditioning or a ComposableScheduledPromptConditioning or a ScheduledPromptConditioning or a list of these components,
            # if XXX is a positive prompt, you should call mark_prompt_context(XXX, positive=True)
            # if XXX is a negative prompt, you should call mark_prompt_context(XXX, positive=False)
            # After you mark the prompts, the ControlNet will know which prompt is cond/uncond and works as expected.
            # After you mark the prompts, the mismatch errors will disappear.
            mark_prompt_context(kwargs.get('conditioning', []), positive=True)
            mark_prompt_context(kwargs.get('unconditional_conditioning', []), positive=False)
            mark_prompt_context(getattr(process, 'hr_c', []), positive=True)
            mark_prompt_context(getattr(process, 'hr_uc', []), positive=False)
            return process.sample_before_CN_hack(*args, **kwargs)

        def forward(self, x, timesteps=None, context=None, **kwargs):
            total_controlnet_embedding = [0.0] * 13
            total_t2i_adapter_embedding = [0.0] * 4
            require_inpaint_hijack = False
            is_in_high_res_fix = False
            batch_size = int(x.shape[0])

            # Handle cond-uncond marker
            cond_mark, outer.current_uc_indices, context = unmark_prompt_context(context)
            # logger.info(str(cond_mark[:, 0, 0, 0].detach().cpu().numpy().tolist()) + ' - ' + str(outer.current_uc_indices))

            # High-res fix
            for param in outer.control_params:
                # select which hint_cond to use
                if param.used_hint_cond is None:
                    param.used_hint_cond = param.hint_cond
                    param.used_hint_cond_latent = None
                    param.used_hint_inpaint_hijack = None

                # has high-res fix
                if param.hr_hint_cond is not None and x.ndim == 4 and param.hint_cond.ndim == 4 and param.hr_hint_cond.ndim == 4:
                    _, _, h_lr, w_lr = param.hint_cond.shape
                    _, _, h_hr, w_hr = param.hr_hint_cond.shape
                    _, _, h, w = x.shape
                    h, w = h * 8, w * 8
                    if abs(h - h_lr) < abs(h - h_hr):
                        is_in_high_res_fix = False
                        if param.used_hint_cond is not param.hint_cond:
                            param.used_hint_cond = param.hint_cond
                            param.used_hint_cond_latent = None
                            param.used_hint_inpaint_hijack = None
                    else:
                        is_in_high_res_fix = True
                        if param.used_hint_cond is not param.hr_hint_cond:
                            param.used_hint_cond = param.hr_hint_cond
                            param.used_hint_cond_latent = None
                            param.used_hint_inpaint_hijack = None

            # Convert control image to latent
            for param in outer.control_params:
                if param.used_hint_cond_latent is not None:
                    continue
                if param.control_model_type not in [ControlModelType.AttentionInjection] \
                        and 'colorfix' not in param.preprocessor['name'] \
                        and 'inpaint_only' not in param.preprocessor['name']:
                    continue
                param.used_hint_cond_latent = outer.call_vae_using_process(process, param.used_hint_cond, batch_size=batch_size)

            # handle prompt token control
            for param in outer.control_params:
                if param.guidance_stopped:
                    continue

                if param.control_model_type not in [ControlModelType.T2I_StyleAdapter]:
                    continue

                param.control_model.to(devices.get_device_for("controlnet"))
                control = param.control_model(x=x, hint=param.used_hint_cond, timesteps=timesteps, context=context)
                control = torch.cat([control.clone() for _ in range(batch_size)], dim=0)
                control *= param.weight
                control *= cond_mark[:, :, :, 0]
                context = torch.cat([context, control.clone()], dim=1)

            # handle ControlNet / T2I_Adapter
            for param in outer.control_params:
                if param.guidance_stopped:
                    continue

                if param.control_model_type not in [ControlModelType.ControlNet, ControlModelType.T2I_Adapter]:
                    continue

                param.control_model.to(devices.get_device_for("controlnet"))
                # inpaint model workaround
                x_in = x
                control_model = param.control_model.control_model

                if param.control_model_type == ControlModelType.ControlNet:
                    if x.shape[1] != control_model.input_blocks[0][0].in_channels and x.shape[1] == 9:
                        # inpaint_model: 4 data + 4 downscaled image + 1 mask
                        x_in = x[:, :4, ...]
                        require_inpaint_hijack = True

                assert param.used_hint_cond is not None, f"Controlnet is enabled but no input image is given"

                hint = param.used_hint_cond

                # ControlNet inpaint protocol
                if hint.shape[1] == 4:
                    c = hint[:, 0:3, :, :]
                    m = hint[:, 3:4, :, :]
                    m = (m > 0.5).float()
                    hint = c * (1 - m) - m

                control = param.control_model(x=x_in, hint=hint, timesteps=timesteps, context=context)
                control_scales = ([param.weight] * 13)

                if outer.lowvram:
                    param.control_model.to("cpu")

                if param.cfg_injection or param.global_average_pooling:
                    if param.control_model_type == ControlModelType.T2I_Adapter:
                        control = [torch.cat([c.clone() for _ in range(batch_size)], dim=0) for c in control]
                    control = [c * cond_mark for c in control]

                high_res_fix_forced_soft_injection = False

                if is_in_high_res_fix:
                    if 'canny' in param.preprocessor['name']:
                        high_res_fix_forced_soft_injection = True
                    if 'mlsd' in param.preprocessor['name']:
                        high_res_fix_forced_soft_injection = True

                # if high_res_fix_forced_soft_injection:
                #     logger.info('[ControlNet] Forced soft_injection in high_res_fix in enabled.')

                if param.soft_injection or high_res_fix_forced_soft_injection:
                    # important! use the soft weights with high-res fix can significantly reduce artifacts.
                    if param.control_model_type == ControlModelType.T2I_Adapter:
                        control_scales = [param.weight * x for x in (0.25, 0.62, 0.825, 1.0)]
                    elif param.control_model_type == ControlModelType.ControlNet:
                        control_scales = [param.weight * (0.825 ** float(12 - i)) for i in range(13)]

                if param.advanced_weighting is not None:
                    control_scales = param.advanced_weighting

                control = [c * scale for c, scale in zip(control, control_scales)]
                if param.global_average_pooling:
                    control = [torch.mean(c, dim=(2, 3), keepdim=True) for c in control]

                for idx, item in enumerate(control):
                    target = None
                    if param.control_model_type == ControlModelType.ControlNet:
                        target = total_controlnet_embedding
                    if param.control_model_type == ControlModelType.T2I_Adapter:
                        target = total_t2i_adapter_embedding
                    if target is not None:
                        target[idx] = item + target[idx]

            # Replace x_t to support inpaint models
            for param in outer.control_params:
                if param.used_hint_cond.shape[1] != 4:
                    continue
                if x.shape[1] != 9:
                    continue
                if param.used_hint_inpaint_hijack is None:
                    mask_pixel = param.used_hint_cond[:, 3:4, :, :]
                    image_pixel = param.used_hint_cond[:, 0:3, :, :]
                    mask_pixel = (mask_pixel > 0.5).to(mask_pixel.dtype)
                    masked_latent = outer.call_vae_using_process(process, image_pixel, batch_size, mask=mask_pixel)
                    mask_latent = torch.nn.functional.max_pool2d(mask_pixel, (8, 8))
                    if mask_latent.shape[0] != batch_size:
                        mask_latent = torch.cat([mask_latent.clone() for _ in range(batch_size)], dim=0)
                    param.used_hint_inpaint_hijack = torch.cat([mask_latent, masked_latent], dim=1)
                    param.used_hint_inpaint_hijack.to(x.dtype).to(x.device)
                x = torch.cat([x[:, :4, :, :], param.used_hint_inpaint_hijack], dim=1)

            # A1111 fix for medvram.
            if shared.cmd_opts.medvram:
                try:
                    # Trigger the register_forward_pre_hook
                    outer.sd_ldm.model()
                except:
                    pass

            # Clear attention and AdaIn cache
            for module in outer.attn_module_list:
                module.bank = []
                module.style_cfgs = []
            for module in outer.gn_module_list:
                module.mean_bank = []
                module.var_bank = []
                module.style_cfgs = []

            # Handle attention and AdaIn control
            for param in outer.control_params:
                if param.guidance_stopped:
                    continue

                if param.used_hint_cond_latent is None:
                    continue

                if param.control_model_type not in [ControlModelType.AttentionInjection]:
                    continue

                ref_xt = outer.sd_ldm.q_sample(param.used_hint_cond_latent, torch.round(timesteps.float()).long())

                # Inpaint Hijack
                if x.shape[1] == 9:
                    ref_xt = torch.cat([
                        ref_xt,
                        torch.zeros_like(ref_xt)[:, 0:1, :, :],
                        param.used_hint_cond_latent
                    ], dim=1)

                outer.current_style_fidelity = float(param.preprocessor['threshold_a'])
                outer.current_style_fidelity = max(0.0, min(1.0, outer.current_style_fidelity))

                if param.cfg_injection:
                    outer.current_style_fidelity = 1.0
                elif param.soft_injection or is_in_high_res_fix:
                    outer.current_style_fidelity = 0.0

                control_name = param.preprocessor['name']

                if control_name in ['reference_only', 'reference_adain+attn']:
                    outer.attention_auto_machine = AutoMachine.Write
                    outer.attention_auto_machine_weight = param.weight

                if control_name in ['reference_adain', 'reference_adain+attn']:
                    outer.gn_auto_machine = AutoMachine.Write
                    outer.gn_auto_machine_weight = param.weight

                outer.original_forward(
                    x=ref_xt.to(devices.dtype_unet),
                    timesteps=timesteps.to(devices.dtype_unet),
                    context=context.to(devices.dtype_unet)
                )

                outer.attention_auto_machine = AutoMachine.Read
                outer.gn_auto_machine = AutoMachine.Read

            # U-Net Encoder
            hs = []
            with th.no_grad():
                t_emb = cond_cast_unet(timestep_embedding(timesteps, self.model_channels, repeat_only=False))
                emb = self.time_embed(t_emb)
                h = x.type(self.dtype)
                for i, module in enumerate(self.input_blocks):
                    h = module(h, emb, context)

                    if (i + 1) % 3 == 0:
                        h = aligned_adding(h, total_t2i_adapter_embedding.pop(0), require_inpaint_hijack)

                    hs.append(h)
                h = self.middle_block(h, emb, context)

            # U-Net Middle Block
            h = aligned_adding(h, total_controlnet_embedding.pop(), require_inpaint_hijack)

            # U-Net Decoder
            for i, module in enumerate(self.output_blocks):
                h = th.cat([h, aligned_adding(hs.pop(), total_controlnet_embedding.pop(), require_inpaint_hijack)], dim=1)
                h = module(h, emb, context)

            # U-Net Output
            h = h.type(x.dtype)
            h = self.out(h)

            # Post-processing for color fix
            for param in outer.control_params:
                if param.used_hint_cond_latent is None:
                    continue
                if 'colorfix' not in param.preprocessor['name']:
                    continue

                k = int(param.preprocessor['threshold_a'])
                if is_in_high_res_fix:
                    k *= 2

                # Inpaint hijack
                xt = x[:, :4, :, :]

                x0_origin = param.used_hint_cond_latent
                t = torch.round(timesteps.float()).long()
                x0_prd = predict_start_from_noise(outer.sd_ldm, xt, t, h)
                x0 = x0_prd - blur(x0_prd, k) + blur(x0_origin, k)

                if '+sharp' in param.preprocessor['name']:
                    detail_weight = float(param.preprocessor['threshold_b']) * 0.01
                    neg = detail_weight * blur(x0, k) + (1 - detail_weight) * x0
                    x0 = cond_mark * x0 + (1 - cond_mark) * neg

                eps_prd = predict_noise_from_start(outer.sd_ldm, xt, t, x0)

                w = max(0.0, min(1.0, float(param.weight)))
                h = eps_prd * w + h * (1 - w)

            # Post-processing for restore
            for param in outer.control_params:
                if param.used_hint_cond_latent is None:
                    continue
                if 'inpaint_only' not in param.preprocessor['name']:
                    continue
                if param.used_hint_cond.shape[1] != 4:
                    continue

                # Inpaint hijack
                xt = x[:, :4, :, :]

                mask = param.used_hint_cond[:, 3:4, :, :]
                mask = torch.nn.functional.max_pool2d(mask, (10, 10), stride=(8, 8), padding=1)

                x0_origin = param.used_hint_cond_latent
                t = torch.round(timesteps.float()).long()
                x0_prd = predict_start_from_noise(outer.sd_ldm, xt, t, h)
                x0 = x0_prd * mask + x0_origin * (1 - mask)
                eps_prd = predict_noise_from_start(outer.sd_ldm, xt, t, x0)

                w = max(0.0, min(1.0, float(param.weight)))
                h = eps_prd * w + h * (1 - w)

            return h

        def forward_webui(*args, **kwargs):
            # webui will handle other compoments 
            try:
                if shared.cmd_opts.lowvram:
                    lowvram.send_everything_to_cpu()

                return forward(*args, **kwargs)
            finally:
                if self.lowvram:
                    for param in self.control_params:
                        if isinstance(param.control_model, torch.nn.Module):
                            param.control_model.to("cpu")

        def hacked_basic_transformer_inner_forward(self, x, context=None):
            x_norm1 = self.norm1(x)
            self_attn1 = None
            if self.disable_self_attn:
                # Do not use self-attention
                self_attn1 = self.attn1(x_norm1, context=context)
            else:
                # Use self-attention
                self_attention_context = x_norm1
                if outer.attention_auto_machine == AutoMachine.Write:
                    if outer.attention_auto_machine_weight > self.attn_weight:
                        self.bank.append(self_attention_context.detach().clone())
                        self.style_cfgs.append(outer.current_style_fidelity)
                if outer.attention_auto_machine == AutoMachine.Read:
                    if len(self.bank) > 0:
                        style_cfg = sum(self.style_cfgs) / float(len(self.style_cfgs))
                        self_attn1_uc = self.attn1(x_norm1, context=torch.cat([self_attention_context] + self.bank, dim=1))
                        self_attn1_c = self_attn1_uc.clone()
                        if len(outer.current_uc_indices) > 0 and style_cfg > 1e-5:
                            self_attn1_c[outer.current_uc_indices] = self.attn1(
                                x_norm1[outer.current_uc_indices],
                                context=self_attention_context[outer.current_uc_indices])
                        self_attn1 = style_cfg * self_attn1_c + (1.0 - style_cfg) * self_attn1_uc
                    self.bank = []
                    self.style_cfgs = []
                if self_attn1 is None:
                    self_attn1 = self.attn1(x_norm1, context=self_attention_context)

            x = self_attn1.to(x.dtype) + x
            x = self.attn2(self.norm2(x), context=context) + x
            x = self.ff(self.norm3(x)) + x
            return x

        def hacked_group_norm_forward(self, *args, **kwargs):
            eps = 1e-6
            x = self.original_forward(*args, **kwargs)
            y = None
            if outer.gn_auto_machine == AutoMachine.Write:
                if outer.gn_auto_machine_weight > self.gn_weight:
                    var, mean = torch.var_mean(x, dim=(2, 3), keepdim=True, correction=0)
                    self.mean_bank.append(mean)
                    self.var_bank.append(var)
                    self.style_cfgs.append(outer.current_style_fidelity)
            if outer.gn_auto_machine == AutoMachine.Read:
                if len(self.mean_bank) > 0 and len(self.var_bank) > 0:
                    style_cfg = sum(self.style_cfgs) / float(len(self.style_cfgs))
                    var, mean = torch.var_mean(x, dim=(2, 3), keepdim=True, correction=0)
                    std = torch.maximum(var, torch.zeros_like(var) + eps) ** 0.5
                    mean_acc = sum(self.mean_bank) / float(len(self.mean_bank))
                    var_acc = sum(self.var_bank) / float(len(self.var_bank))
                    std_acc = torch.maximum(var_acc, torch.zeros_like(var_acc) + eps) ** 0.5
                    y_uc = (((x - mean) / std) * std_acc) + mean_acc
                    y_c = y_uc.clone()
                    if len(outer.current_uc_indices) > 0 and style_cfg > 1e-5:
                        y_c[outer.current_uc_indices] = x.to(y_c.dtype)[outer.current_uc_indices]
                    y = style_cfg * y_c + (1.0 - style_cfg) * y_uc
                self.mean_bank = []
                self.var_bank = []
                self.style_cfgs = []
            if y is None:
                y = x
            return y.to(x.dtype)

        if getattr(process, 'sample_before_CN_hack', None) is None:
            process.sample_before_CN_hack = process.sample
        process.sample = process_sample

        model._original_forward = model.forward
        outer.original_forward = model.forward
        model.forward = forward_webui.__get__(model, UNetModel)

        all_modules = torch_dfs(model)

        attn_modules = [module for module in all_modules if isinstance(module, BasicTransformerBlock)]
        attn_modules = sorted(attn_modules, key=lambda x: - x.norm1.normalized_shape[0])

        for i, module in enumerate(attn_modules):
            if getattr(module, '_original_inner_forward', None) is None:
                module._original_inner_forward = module._forward
            module._forward = hacked_basic_transformer_inner_forward.__get__(module, BasicTransformerBlock)
            module.bank = []
            module.style_cfgs = []
            module.attn_weight = float(i) / float(len(attn_modules))

        gn_modules = [model.middle_block]
        model.middle_block.gn_weight = 0

        input_block_indices = [4, 5, 7, 8, 10, 11]
        for w, i in enumerate(input_block_indices):
            module = model.input_blocks[i]
            module.gn_weight = 1.0 - float(w) / float(len(input_block_indices))
            gn_modules.append(module)

        output_block_indices = [0, 1, 2, 3, 4, 5, 6, 7]
        for w, i in enumerate(output_block_indices):
            module = model.output_blocks[i]
            module.gn_weight = float(w) / float(len(output_block_indices))
            gn_modules.append(module)

        for i, module in enumerate(gn_modules):
            if getattr(module, 'original_forward', None) is None:
                module.original_forward = module.forward
            module.forward = hacked_group_norm_forward.__get__(module, torch.nn.Module)
            module.mean_bank = []
            module.var_bank = []
            module.style_cfgs = []
            module.gn_weight *= 2

        outer.attn_module_list = attn_modules
        outer.gn_module_list = gn_modules

        scripts.script_callbacks.on_cfg_denoiser(self.guidance_schedule_handler)

    def restore(self, model):
        scripts.script_callbacks.remove_callbacks_for_function(self.guidance_schedule_handler)
        if hasattr(self, "control_params"):
            del self.control_params

        if not hasattr(model, "_original_forward"):
            # no such handle, ignore
            return

        model.forward = model._original_forward
        del model._original_forward
